Multiple nozzle gas cluster ion beam processing system and method of operating

ABSTRACT

A gas cluster ion beam (GCIB) processing system using multiple nozzles for forming and emitting at least one GCIB and methods of operating thereof are described. The GCIB processing system may be configured to treat a substrate, including, but not limited to, doping, growing, depositing, etching, smoothing, amorphizing, or modifying a layer thereupon. Furthermore, the GCIB processing system may be operated to produce a first GCIB and a second GCIB, and to irradiate a substrate simultaneously and/or sequentially with the first GCIB and second GCIB.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of U.S. Nonprovisional application Ser. No. 12/428,945, entitled “MULTIPLE NOZZLE GAS CLUSTER ION BEAM SYSTEM”, filed on Apr. 23, 2009, which, pursuant to 37 C.F.R. §1.78(a)(4), is based on and claims the benefit of and priority to U.S. Provisional Patent Application No. 61/149,930, entitled “MULTIPLE NOZZLE GAS CLUSTER ION BEAM SYSTEM AND A METHOD OF OPERATION”, filed on Feb. 4, 2009. This application is related to co-pending U.S. Nonprovisional patent application Ser. No. 12/367,697, entitled “METHOD FOR FORMING TRENCH ISOLATION USING A GAS CLUSTER ION BEAM GROWTH PROCESS”, filed on Feb. 9, 2009, and U.S. Provisional Patent Application No. 61/149,917, entitled “METHOD FOR FORMING TRENCH ISOLATION USING GAS CLUSTER ION BEAM PROCESSING”, filed on Feb. 4, 2009. This application is also related to co-pending U.S. patent application Ser. No. 12/428,973 entitled “METHOD OF IRRADIATING SUBSTRATE WITH GAS CLUSTER ION BEAM FORMED FROM MULTIPLE GAS NOZZLES”, and co-pending U.S. patent application Ser. No. 12/428,856 entitled “METHOD FOR FORMING TRENCH ISOLATION USING GAS CLUSTER ION BEAM PROCESSING”, each filed on even date herewith. The entire contents of all of these applications are herein incorporated by reference in their entirety.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The invention relates to a system with multiple nozzles for irradiating substrates using a gas cluster ion beam (GCIB), and a method for irradiating substrates to treat layers on a substrate using the multiple nozzle GCIB processing system.

2. Description of Related Art

Gas cluster ion beams (GCIB's) are used for doping, etching, cleaning, smoothing, and growing or depositing layers on a substrate. For purposes of this discussion, gas clusters are nano-sized aggregates of materials that are gaseous under conditions of standard temperature and pressure. Such gas clusters may consist of aggregates including a few to several thousand molecules, or more, that are loosely bound together. The gas clusters can be ionized by electron bombardment, which permits the gas clusters to be formed into directed beams of controllable energy. Such cluster ions each typically carry positive charges given by the product of the magnitude of the electronic charge and an integer greater than or equal to one that represents the charge state of the cluster ion. The larger sized cluster ions are often the most useful because of their ability to carry substantial energy per cluster ion, while yet having only modest energy per individual molecule. The ion clusters disintegrate on impact with the substrate. Each individual molecule in a particular disintegrated ion cluster carries only a small fraction of the total cluster energy. Consequently, the impact effects of large ion clusters are substantial, but are limited to a very shallow surface region. This makes gas cluster ions effective for a variety of surface modification processes, but without the tendency to produce deeper sub-surface damage that is characteristic of conventional ion beam processing.

Conventional cluster ion sources produce cluster ions having a wide size distribution scaling with the number of molecules in each cluster that may reach several thousand molecules. Clusters of atoms can be formed by the condensation of individual gas atoms (or molecules) during the adiabatic expansion of high pressure gas from a nozzle into a vacuum. A gas skimmer with a small aperture strips divergent streams from the core of this expanding gas flow to produce a collimated beam of clusters. Neutral clusters of various sizes are produced and held together by weak inter-atomic forces known as Van der Waals forces. This method has been used to produce beams of clusters from a variety of gases, such as helium, neon, argon, krypton, xenon, nitrogen, oxygen, carbon dioxide, sulfur hexafluoride, nitric oxide, nitrous oxide, and mixtures of these gases. Several emerging applications for GCIB processing of substrates on an industrial scale are in the semiconductor field. Although GCIB processing of a substrate is performed using a wide variety of gas-cluster source gases, many of which are inert gases, many semiconductor processing applications use reactive source gases, sometimes in combination or mixture with inert or noble gases, to form the GCIB. Certain gas or gas mixture combinations are incompatible due to their reactivity, so a need exists for a GCIB system which overcomes the incompatibility problem.

SUMMARY OF THE INVENTION

The present invention relates to an assembly and system with multiple nozzles for irradiating substrates using a gas cluster ion beam (GCIB), and associated methods for irradiating substrates to treat layers on a substrate using a multiple nozzle GCIB processing system. Further, the present invention relates to an assembly and system with multiple nozzles for irradiating substrates using a GCIB, and associated methods for sequentially irradiating substrates to treat layers on a substrate using a multiple nozzle GCIB processing system.

According to an embodiment, a method of irradiating a substrate with a GCIB is provided. The method comprises providing a GCIB processing system comprising a set of at least two nozzles for forming and emitting gas cluster beams. The method further comprises loading a substrate to be processed into the GCIB processing system, irradiating at least one region on the substrate with a first GCIB formed using the set of at least two nozzles; and irradiating at least one region on the substrate with a second GCIB formed using the set of at least two nozzles, wherein the first GCIB and the second GCIB are directed along a beam axis common to both the first and second GCIB.

According to yet another embodiment, a method of irradiating a substrate with a GCIB is provided. The method comprises providing a GCIB processing system having a set of at least two nozzles for forming and emitting gas cluster beams, and loading a substrate to be processed into the GCIB processing system. The method further comprises sequentially first irradiating at least one region on the substrate with a first GCIB formed using a first subset of nozzles in the set of at least two nozzles, and sequentially second irradiating at least one region on the substrate with a second GCIB formed using a second subset of nozzles in the set of at least two nozzles that is different than the first subset of nozzles.

BRIEF DESCRIPTION OF THE DRAWINGS

A more complete appreciation of the invention and many of the attendant advantages thereof will become readily apparent with reference to the following detailed description, particularly when considered in conjunction with the accompanying drawings, in which:

FIG. 1 is a schematic representation of a multiple nozzle GCIB processing system in accordance with an embodiment of the invention.

FIG. 2 is a schematic representation of a multiple nozzle GCIB processing system in accordance with another embodiment of the invention.

FIG. 3 is a schematic representation of a multiple nozzle GCIB processing system in accordance with yet another embodiment of the invention.

FIG. 4 is a schematic representation of an embodiment of an ionizer for use in a GCIB processing system.

FIGS. 5-9 are schematic representations of various embodiments of the multiple nozzle assembly, comprising multiple nozzles, single or multiple gas supplies, and having various gas flow interconnections provided therebetween.

FIGS. 10A-12B are cross-sectional views of various embodiments of the multiple nozzle assembly depicting various arrangements of multiple nozzles, and having various gas skimmer cross-sectional shapes to accommodate the various nozzle arrangements.

FIG. 13A-D are schematic representations of various embodiments of a multiple nozzle assemblies with nozzles mounted at an inwards pointing angle such that gas cluster beams intersect at a point along the main GCIB axis.

FIG. 14 is a flowchart of an embodiment of a method for operating a GCIB processing system with multiple nozzles.

FIG. 15 is a flowchart of an embodiment of a method for formation of a shallow trench isolation (STI) structure using a GCIB processing system with multiple nozzles.

FIGS. 16A through 16F provide schematic illustrations of methods for operating a GCIB processing system with multiple nozzles according to several embodiments.

FIG. 17 is a flowchart of another embodiment of a method for operating a GCIB processing system with multiple nozzles.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS

In the following description, in order to facilitate a thorough understanding of the invention and for purposes of explanation and not limitation, specific details are set forth, such as a particular geometry of the metrology system and descriptions of various components and processes. However, it should be understood that the invention may be practiced in other embodiments that depart from these specific details.

Referring now to FIG. 1, a GCIB processing system 100 for modifying, depositing, growing, or doping a layer is depicted according to an embodiment. The GCIB processing system 100 comprises a vacuum vessel 102, substrate holder 150, upon which a substrate 152 to be processed is affixed, and vacuum pumping systems 170A, 170B, and 170C. Substrate 152 can be a semiconductor substrate, a wafer, a flat panel display (FPD), a liquid crystal display (LCD), or any other workpiece. GCIB processing system 100 is configured to produce a GCIB for treating substrate 152.

Referring still to GCIB processing system 100 in FIG. 1, the vacuum vessel 102 comprises three communicating chambers, namely, a source chamber 104, an ionization/acceleration chamber 106, and a processing chamber 108 to provide a reduced-pressure enclosure. The three chambers are evacuated to suitable operating pressures by vacuum pumping systems 170A, 170B, and 170C, respectively. In the three communicating chambers 104, 106, 108, a gas cluster beam can be formed in the first chamber (source chamber 104), while a GCIB can be formed in the second chamber (ionization/acceleration chamber 106) wherein the gas cluster beam is ionized and accelerated. Then, in the third chamber (processing chamber 108), the accelerated GCIB may be utilized to treat substrate 152.

In the exemplary embodiment of FIG. 1, GCIB processing system 100 comprises two gas supplies 115, 1015 and two nozzles 116, 1016. Additional embodiments will be discussed later having numbers of nozzles different than two, and numbers of gas supplies different than two, all of which fall within the scope of the invention. Each of the two gas supplies 115 and 1015 is connected to one of two stagnation chambers 116 and 1016, and nozzles 110 and 1010, respectively. The first gas supply 115 comprises a first gas source 111, a second gas source 112, a first gas control valve 113A, a second gas control valve 113B, and a gas metering valve 113. For example, a first gas composition stored in the first gas source 111 is admitted under pressure through a first gas control valve 113A to the gas metering valve or valves 113. Additionally, for example, a second gas composition stored in the second gas source 112 is admitted under pressure through the second gas control valve 113B to the gas metering valve or valves 113. Further, for example, the first gas composition or second gas composition, or both, of first gas supply 115 can include a condensable inert gas, carrier gas or dilution gas. For example, the inert gas, carrier gas or dilution gas can include a noble gas, i.e., He, Ne, Ar, Kr, Xe, or Rn.

Similarly, the second gas supply 1015 comprises a first gas source 1011, a second gas source 1012, a first gas control valve 1013A, a second gas control valve 1013B, and a gas metering valve 1013. For example, a first gas composition stored in the first gas source 1011 is admitted under pressure through the first gas control valve 1013A to the gas metering valve or valves 1013. Additionally, for example, a second gas composition stored in the second gas source 1012 is admitted under pressure through the second gas control valve 1013B to the gas metering valve or valves 1013. Further, for example, the first gas composition or second gas composition, or both, of second gas supply 1015 can include a condensable inert gas, carrier gas or dilution gas. For example, the inert gas, carrier gas or dilution gas can include a noble gas, i.e., He, Ne, Ar, Kr, Xe, or Rn.

Furthermore, the first gas sources 111 and 1011, and the second gas sources 112 and 1012 are each utilized to produce ionized clusters. The material compositions of the first and second gas sources 111, 1011, 112, and 1012 include the principal atomic (or molecular) species, i.e., the first and second atomic constituents desired to be introduced for doping, depositing, modifying, or growing a layer.

The high pressure, condensable gas comprising the first gas composition and/or the second gas composition is introduced from the first gas supply 115 through gas feed tube 114 into stagnation chamber 116 and is ejected into the substantially lower pressure vacuum through a properly shaped nozzle 110. As a result of the expansion of the high pressure, condensable gas from the stagnation chamber 116 to the lower pressure region of the source chamber 104, the gas velocity accelerates to supersonic speeds and a gas cluster beam emanates from nozzle 110.

Similarly, the high pressure, condensable gas comprising the first gas composition and/or the second gas composition is introduced from the second gas supply 1015 through gas feed tube 1014 into stagnation chamber 1016 and is ejected into the substantially lower pressure vacuum through a properly shaped nozzle 1010. As a result of the expansion of the high pressure, condensable gas from the stagnation chamber 1016 to the lower pressure region of the source chamber 104, the gas velocity accelerates to supersonic speeds and a gas cluster beam emanates from nozzle 1010.

Nozzles 110 and 1010 are mounted in such close proximity that the individual gas cluster beams generated by the nozzles 110, 1010 substantially coalesce in the vacuum environment of source chamber 104 into a single gas cluster beam 118 before reaching the gas skimmer 120. The chemical composition of the gas cluster beam 118 represents a mixture of compositions provided by the first and second gas supplies 115 and 1015, injected via nozzles 110 and 1010.

The inherent cooling of the jet as static enthalpy is exchanged for kinetic energy, which results from the expansion in the jets, causes a portion of the gas jets to condense and form a gas cluster beam 118 having clusters, each consisting of from several to several thousand weakly bound atoms or molecules. A gas skimmer 120, positioned downstream from the exit of nozzles 110 and 1010 between the source chamber 104 and ionization/acceleration chamber 106, partially separates the gas molecules on the peripheral edge of the gas cluster beam 118, that may not have condensed into a cluster, from the gas molecules in the core of the gas cluster beam 118, that may have formed clusters. Among other reasons, this selection of a portion of gas cluster beam 118 can lead to a reduction in the pressure in the downstream regions where higher pressures may be detrimental (e.g., ionizer 122, and processing chamber 108). Furthermore, gas skimmer 120 defines an initial dimension for the gas cluster beam entering the ionization/acceleration chamber 106.

The first and second gas supplies 115 and 1015 can be configured to independently control stagnation pressures and temperatures of gas mixtures introduced to stagnation chambers 116 and 1016. Temperature control can be achieved by the use of suitable temperature control systems (e.g. heaters and/or coolers) in each gas supply (not shown). In addition, a manipulator 117 may be mechanically coupled to nozzle 110, for example via the stagnation chamber 116, the manipulator 117 being configured to position the coupled nozzle 110 with respect to the gas skimmer 120, independent of nozzle 1010. Likewise, a manipulator 1017 may be mechanically coupled to nozzle 1010, for example via the stagnation chamber 1016, the manipulator 1017 being configured to position the coupled nozzle 1010 with respect to the gas skimmer 120, independent of nozzle 110. Thus each nozzle in a multi-nozzle assembly may be separately manipulated for proper positioning vis-à-vis the single gas skimmer 120.

After the gas cluster beam 118 has been formed in the source chamber 104, the constituent gas clusters in gas cluster beam 118 are ionized by ionizer 122 to form GCIB 128. The ionizer 122 may include an electron impact ionizer that produces electrons from one or more filaments 124, which are accelerated and directed to collide with the gas clusters in the gas cluster beam 118 inside the ionization/acceleration chamber 106. Upon collisional impact with the gas cluster, electrons of sufficient energy eject electrons from molecules in the gas clusters to generate ionized molecules. The ionization of gas clusters can lead to a population of charged gas cluster ions, generally having a net positive charge.

As shown in FIG. 1, beam electronics 130 are utilized to ionize, extract, accelerate, and focus the GCIB 128. The beam electronics 130 include a filament power supply 136 that provides voltage V_(F) to heat the ionizer filament 124.

Additionally, the beam electronics 130 include a set of suitably biased high voltage electrodes 126 in the ionization/acceleration chamber 106 that extracts the cluster ions from the ionizer 122. The high voltage electrodes 126 then accelerate the extracted cluster ions to a desired energy and focus them to define GCIB 128. The kinetic energy of the cluster ions in GCIB 128 typically ranges from about 1000 electron volts (1 keV) to several tens of keV. For example, GCIB 128 can be accelerated to 1 to 100 keV.

As illustrated in FIG. 1, the beam electronics 130 further include an anode power supply 134 that provides voltage V_(A) to an anode of ionizer 122 for accelerating electrons emitted from ionizer filament 124 and causing the electrons to bombard the gas clusters in gas cluster beam 118, which produces cluster ions.

Additionally, as illustrated in FIG. 1, the beam electronics 130 include an extraction power supply 138 that provides voltage V_(E) to bias at least one of the high voltage electrodes 126 to extract ions from the ionizing region of ionizer 122 and to form the GCIB 128. For example, extraction power supply 138 provides a voltage to a first electrode of the high voltage electrodes 126 that is less than or equal to the anode voltage of ionizer 122.

Furthermore, the beam electronics 130 can include an accelerator power supply 140 that provides voltage V_(Acc) to bias one of the high voltage electrodes 126 with respect to the ionizer 122 so as to result in a total GCIB acceleration energy equal to about V_(Acc) electron volts (eV). For example, accelerator power supply 140 provides a voltage to a second electrode of the high voltage electrodes 126 that is less than or equal to the anode voltage of ionizer 122 and the extraction voltage of the first electrode.

Further yet, the beam electronics 130 can include lens power supplies 142, 144 that may be provided to bias some of the high voltage electrodes 126 with potentials (e.g., V_(L1) and V_(L2)) to focus the GCIB 128. For example, lens power supply 142 can provide a voltage to a third electrode of the high voltage electrodes 126 that is less than or equal to the anode voltage of ionizer 122, the extraction voltage of the first electrode, and the accelerator voltage of the second electrode, and lens power supply 144 can provide a voltage to a fourth electrode of the high voltage electrodes 126 that is less than or equal to the anode voltage of ionizer 122, the extraction voltage of the first electrode, the accelerator voltage of the second electrode, and the first lens voltage of the third electrode.

Note that many variants on both the ionization and extraction schemes may be used. While the scheme described here is useful for purposes of instruction, another extraction scheme involves placing the ionizer and the first element of the extraction electrode(s) (or extraction optics) at V_(Acc). This typically requires fiber optic programming of control voltages for the ionizer power supply, but creates a simpler overall optics train. The invention described herein is useful regardless of the details of the ionizer and extraction lens biasing.

A beam filter 146 in the ionization/acceleration chamber 106 downstream of the high voltage electrodes 126 can be utilized to eliminate monomers, or monomers and light cluster ions from the GCIB 128 to define a filtered process GCIB 128A that enters the processing chamber 108. In one embodiment, the beam filter 146 substantially reduces the number of clusters having 100 or less atoms or molecules or both. The beam filter 146 may comprise a magnet assembly for imposing a magnetic field across the GCIB 128 to aid in the filtering process.

Referring still to FIG. 1, a beam gate 148 is disposed in the path of GCIB 128 in the ionization/acceleration chamber 106. Beam gate 148 has an open state in which the GCIB 128 is permitted to pass from the ionization/acceleration chamber 106 to the processing chamber 108 to define process GCIB 128A, and a closed state in which the GCIB 128 is blocked from entering the processing chamber 108. A control cable conducts control signals from control system 190 to beam gate 148. The control signals controllably switch beam gate 148 between the open or closed states.

A substrate 152, which may be a wafer or semiconductor wafer, a flat panel display (FPD), a liquid crystal display (LCD), or other substrate to be processed by GCIB processing, is disposed in the path of the process GCIB 128A in the processing chamber 108. Because most applications contemplate the processing of large substrates with spatially uniform results, a scanning system may be desirable to uniformly scan the process GCIB 128A across large areas to produce spatially homogeneous results.

An X-scan actuator 160 provides linear motion of the substrate holder 150 in the direction of X-scan motion (into and out of the plane of the paper). A Y-scan actuator 162 provides linear motion of the substrate holder 150 in the direction of Y-scan motion 164, which is typically orthogonal to the X-scan motion. The combination of X-scanning and Y-scanning motions translates the substrate 152, held by the substrate holder 150, in a raster-like scanning motion through process GCIB 128A to cause a uniform (or otherwise programmed) irradiation of a surface of the substrate 152 by the process GCIB 128A for processing of the substrate 152.

The substrate holder 150 disposes the substrate 152 at an angle with respect to the axis of the process GCIB 128A so that the process GCIB 128A has an angle of beam incidence 166 with respect to a substrate 152 surface. The angle of beam incidence 166 may be 90 degrees or some other angle, but is typically 90 degrees or near 90 degrees. During Y-scanning, the substrate 152 and the substrate holder 150 move from the shown position to the alternate position “A” indicated by the designators 152A and 150A, respectively. Notice that in moving between the two positions, the substrate 152 is scanned through the process GCIB 128A, and in both extreme positions, is moved completely out of the path of the process GCIB 128A (over-scanned). Though not shown explicitly in FIG. 1, similar scanning and over-scan is performed in the (typically) orthogonal X-scan motion direction (in and out of the plane of the paper).

A beam current sensor 180 may be disposed beyond the substrate holder 150 in the path of the process GCIB 128A so as to intercept a sample of the process GCIB 128A when the substrate holder 150 is scanned out of the path of the process GCIB 128A. The beam current sensor 180 is typically a faraday cup or the like, closed except for a beam-entry opening, and is typically affixed to the wall of the vacuum vessel 102 with an electrically insulating mount 182.

As shown in FIG. 1, control system 190 connects to the X-scan actuator 160 and the Y-scan actuator 162 through electrical cable and controls the X-scan actuator 160 and the Y-scan actuator 162 in order to place the substrate 152 into or out of the process GCIB 128A and to scan the substrate 152 uniformly relative to the process GCIB 128A to achieve desired processing of the substrate 152 by the process GCIB 128A. Control system 190 receives the sampled beam current collected by the beam current sensor 180 by way of an electrical cable and, thereby, monitors the GCIB and controls the GCIB dose received by the substrate 152 by removing the substrate 152 from the process GCIB 128A when a predetermined dose has been delivered.

In the embodiment shown in FIG. 2, the GCIB processing system 100′ can be similar to the embodiment of FIG. 1 and further comprise a X-Y positioning table 253 operable to hold and move a substrate 252 in two axes, effectively scanning the substrate 252 relative to the process GCIB 128A. For example, the X-motion can include motion into and out of the plane of the paper, and the Y-motion can include motion along direction 264.

The process GCIB 128A impacts the substrate 252 at a projected impact region 286 on a surface of the substrate 252, and at an angle of beam incidence 266 with respect to the surface of substrate 252. By X-Y motion, the X-Y positioning table 253 can position each portion of a surface of the substrate 252 in the path of process GCIB 128A so that every region of the surface may be made to coincide with the projected impact region 286 for processing by the process GCIB 128A. An X-Y controller 262 provides electrical signals to the X-Y positioning table 253 through an electrical cable for controlling the position and velocity in each of X-axis and Y-axis directions. The X-Y controller 262 receives control signals from, and is operable by, control system 190 through an electrical cable. X-Y positioning table 253 moves by continuous motion or by stepwise motion according to conventional X-Y table positioning technology to position different regions of the substrate 252 within the projected impact region 286. In one embodiment, X-Y positioning table 253 is programmably operable by the control system 190 to scan, with programmable velocity, any portion of the substrate 252 through the projected impact region 286 for GCIB processing by the process GCIB 128A.

The substrate holding surface 254 of positioning table 253 is electrically conductive and is connected to a dosimetry processor operated by control system 190. An electrically insulating layer 255 of positioning table 253 isolates the substrate 252 and substrate holding surface 254 from the base portion 260 of the positioning table 253. Electrical charge induced in the substrate 252 by the impinging process GCIB 128A is conducted through substrate 252 and substrate holding surface 254, and a signal is coupled through the positioning table 253 to control system 190 for dosimetry measurement. Dosimetry measurement has integrating means for integrating the GCIB current to determine a GCIB processing dose. Under certain circumstances, a target-neutralizing source (not shown) of electrons, sometimes referred to as electron flood, may be used to neutralize the process GCIB 128A. In such case, a Faraday cup (not shown, but which may be similar to beam current sensor 180 in FIG. 1) may be used to assure accurate dosimetry despite the added source of electrical charge, the reason being that typical Faraday cups allow only the high energy positive ions to enter and be measured.

In operation, the control system 190 signals the opening of the beam gate 148 to irradiate the substrate 252 with the process GCIB 128A. The control system 190 monitors measurements of the GCIB current collected by the substrate 252 in order to compute the accumulated dose received by the substrate 252. When the dose received by the substrate 252 reaches a predetermined dose, the control system 190 closes the beam gate 148 and processing of the substrate 252 is complete. Based upon measurements of the GCIB dose received for a given area of the substrate 252, the control system 190 can adjust the scan velocity in order to achieve an appropriate beam dwell time to treat different regions of the substrate 252.

Alternatively, the process GCIB 128A may be scanned at a constant velocity in a fixed pattern across the surface of the substrate 252; however, the GCIB intensity is modulated (may be referred to as Z-axis modulation) to deliver an intentionally non-uniform dose to the sample. The GCIB intensity may be modulated in the GCIB processing system 100′ by any of a variety of methods, including varying the gas flow from a GCIB source supply; modulating the ionizer 122 by either varying a filament voltage V_(F) or varying an anode voltage V_(A); modulating the lens focus by varying lens voltages V_(L1) and/or V_(L2); or mechanically blocking a portion of the GCIB with a variable beam block, adjustable shutter, or variable aperture. The modulating variations may be continuous analog variations or may be time modulated switching or gating.

The processing chamber 108 may further include an in-situ metrology system. For example, the in-situ metrology system may include an optical diagnostic system having an optical transmitter 280 and optical receiver 282 configured to illuminate substrate 252 with an incident optical signal 284 and to receive a scattered optical signal 288 from substrate 252, respectively. The optical diagnostic system comprises optical windows to permit the passage of the incident optical signal 284 and the scattered optical signal 288 into and out of the processing chamber 108. Furthermore, the optical transmitter 280 and the optical receiver 282 may comprise transmitting and receiving optics, respectively. The optical transmitter 280 receives, and is responsive to, controlling electrical signals from the control system 190. The optical receiver 282 returns measurement signals to the control system 190.

The in-situ metrology system may comprise any instrument configured to monitor the progress of the GCIB processing. According to one embodiment, the in-situ metrology system may constitute an optical scatterometry system. The scatterometry system may include a scatterometer, incorporating beam profile ellipsometry (ellipsometer) and beam profile reflectometry (reflectometer), commercially available from Therma-Wave, Inc. (1250 Reliance Way, Fremont, Calif. 94539) or Nanometrics, Inc. (1550 Buckeye Drive, Milpitas, Calif. 95035).

For instance, the in-situ metrology system may include an integrated Optical Digital Profilometry (iODP) scatterometry module configured to measure process performance data resulting from the execution of a treatment process in the GCIB processing system 100′. The metrology system may, for example, measure or monitor metrology data resulting from the treatment process. The metrology data can, for example, be utilized to determine process performance data that characterizes the treatment process, such as a process rate, a relative process rate, a feature profile angle, a critical dimension, a feature thickness or depth, a feature shape, etc. For example, in a process for directionally depositing material on a substrate, process performance data can include a critical dimension (CD), such as a top, middle or bottom CD in a feature (i.e., via, line, etc.), a feature depth, a material thickness, a sidewall angle, a sidewall shape, a deposition rate, a relative deposition rate, a spatial distribution of any parameter thereof, a parameter to characterize the uniformity of any spatial distribution thereof, etc. Operating the X-Y positioning table 253 via control signals from control system 190, the in-situ metrology system can map one or more characteristics of the substrate 252.

In the embodiment shown in FIG. 3, the GCIB processing system 100″ can be similar to the embodiment of FIG. 1 and further comprise a pressure cell chamber 350 positioned, for example, at or near an outlet region of the ionization/acceleration chamber 106. The pressure cell chamber 350 comprises an inert gas source 352 configured to supply a background gas to the pressure cell chamber 350 for elevating the pressure in the pressure cell chamber 350, and a pressure sensor 354 configured to measure the elevated pressure in the pressure cell chamber 350.

The pressure cell chamber 350 may be configured to modify the beam energy distribution of GCIB 128 to produce a modified processing GCIB 128A′. This modification of the beam energy distribution is achieved by directing GCIB 128 along a GCIB path through an increased pressure region within the pressure cell chamber 350 such that at least a portion of the GCIB traverses the increased pressure region. The extent of modification to the beam energy distribution may be characterized by a pressure-distance integral along at least a portion of the GCIB path, where distance (or length of the pressure cell chamber 350) is indicated by path length (d). When the value of the pressure-distance integral is increased (either by increasing the pressure and/or the path length (d)), the beam energy distribution is broadened and the peak energy is decreased. When the value of the pressure-distance integral is decreased (either by decreasing the pressure and/or the path length (d)), the beam energy distribution is narrowed and the peak energy is increased. Further details for the design of a pressure cell may be determined from U.S. Pat. No. 7,060,989, entitled METHOD AND APPARATUS FOR IMPROVED PROCESSING WITH A GAS-CLUSTER ION BEAM; the content of which is incorporated herein by reference in its entirety.

Control system 190 comprises a microprocessor, memory, and a digital I/O port capable of generating control voltages sufficient to communicate and activate inputs to GCIB processing system 100 (or 100′, 100″), as well as monitor outputs from GCIB processing system 100 (or 100′, 100″). Moreover, control system 190 can be coupled to and can exchange information with vacuum pumping systems 170A, 170B, and 170C, first gas sources 111 and 1011, second gas sources 112 and 1012, first gas control valves 113A and 1013A, second gas control valves 113B and 1013B, beam electronics 130, beam filter 146, beam gate 148, the X-scan actuator 160, the Y-scan actuator 162, and beam current sensor 180. For example, a program stored in the memory can be utilized to activate the inputs to the aforementioned components of GCIB processing system 100 according to a process recipe in order to perform a GCIB process on substrate 152.

However, the control system 190 may be implemented as a general purpose computer system that performs a portion or all of the microprocessor based processing steps of the invention in response to a processor executing one or more sequences of one or more instructions contained in a memory. Such instructions may be read into the controller memory from another computer readable medium, such as a hard disk or a removable media drive. One or more processors in a multi-processing arrangement may also be employed as the controller microprocessor to execute the sequences of instructions contained in main memory. In alternative embodiments, hard-wired circuitry may be used in place of or in combination with software instructions. Thus, embodiments are not limited to any specific combination of hardware circuitry and software.

The control system 190 can be used to configure any number of processing elements, as described above, and the control system 190 can collect, provide, process, store, and display data from processing elements. The control system 190 can include a number of applications, as well as a number of controllers, for controlling one or more of the processing elements. For example, control system 190 can include a graphic user interface (GUI) component (not shown) that can provide interfaces that enable a user to monitor and/or control one or more processing elements.

Control system 190 can be locally located relative to the GCIB processing system 100 (or 100′, 100″), or it can be remotely located relative to the GCIB processing system 100 (or 100′, 100″). For example, control system 190 can exchange data with GCIB processing system 100 using a direct connection, an intranet, and/or the internet. Control system 190 can be coupled to an intranet at, for example, a customer site (i.e., a device maker, etc.), or it can be coupled to an intranet at, for example, a vendor site (i.e., an equipment manufacturer). Alternatively or additionally, control system 190 can be coupled to the internet. Furthermore, another computer (i.e., controller, server, etc.) can access control system 190 to exchange data via a direct connection, an intranet, and/or the internet.

Substrate 152 (or 252) can be affixed to the substrate holder 150 (or substrate holder 250) via a clamping system (not shown), such as a mechanical clamping system or an electrical clamping system (e.g., an electrostatic clamping system). Furthermore, substrate holder 150 (or 250) can include a heating system (not shown) or a cooling system (not shown) that is configured to adjust and/or control the temperature of substrate holder 150 (or 250) and substrate 152 (or 252).

Vacuum pumping systems 170A, 170B, and 170C can include turbo-molecular vacuum pumps (TMP) capable of pumping speeds up to about 5000 liters per second (and greater) and a gate valve for throttling the chamber pressure. In conventional vacuum processing devices, a 1000 to 3000 liter per second TMP can be employed. TMPs are useful for low pressure processing, typically less than about 50 mTorr. Although not shown, it may be understood that pressure cell chamber 350 may also include a vacuum pumping system. Furthermore, a device for monitoring chamber pressure (not shown) can be coupled to the vacuum vessel 102 or any of the three vacuum chambers 104, 106, 108. The pressure-measuring device can be, for example, a capacitance manometer or ionization gauge.

Also shown in FIGS. 2 and 3 is an alternative embodiment for a nozzle manipulator. Rather than each nozzle 110, 1010 being coupled to a separately operable manipulator 117, 1017 as in FIG. 1, the nozzles 110, 1010 may be coupled to each other, and together coupled to a single manipulator 117A. The position of the nozzles 110, 1010 vis-à-vis the gas skimmer 120 can then be manipulated collectively as a set rather than individually.

Referring now to FIG. 4, a section 300 of a gas cluster ionizer (122, FIGS. 1, 2 and 3) for ionizing a gas cluster jet (gas cluster beam 118, FIGS. 1, 2 and 3) is shown. The section 300 is normal to the axis of GCIB 128. For typical gas cluster sizes (2000 to 15000 atoms), clusters leaving the gas skimmer aperture (120, FIGS. 1, 2 and 3) and entering an ionizer (122, FIGS. 1, 2 and 3) will travel with a kinetic energy of about 130 to 1000 electron volts (eV). At these low energies, any departure from space charge neutrality within the ionizer 122 will result in a rapid dispersion of the jet with a significant loss of beam current. FIG. 4 illustrates a self-neutralizing ionizer. As with other ionizers, gas clusters are ionized by electron impact. In this design, thermo-electrons (seven examples indicated by 310) are emitted from multiple linear thermionic filaments 302 a, 302 b, and 302 c (typically tungsten) and are extracted and focused by the action of suitable electric fields provided by electron-repeller electrodes 306 a, 306 b, and 306 c and beam-forming electrodes 304 a, 304 b, and 304 c. Thermo-electrons 310 pass through the gas cluster jet and the jet axis and then strike the opposite beam-forming electrode 304 b to produce low energy secondary electrons (312, 314, and 316 indicated for examples).

Though (for simplicity) not shown, linear thermionic filaments 302 b and 302 c also produce thermo-electrons that subsequently produce low energy secondary electrons. All the secondary electrons help ensure that the ionized cluster jet remains space charge neutral by providing low energy electrons that can be attracted into the positively ionized gas cluster jet as required to maintain space charge neutrality. Beam-forming electrodes 304 a, 304 b, and 304 c are biased positively with respect to linear thermionic filaments 302 a, 302 b, and 302 c and electron-repeller electrodes 306 a, 306 b, and 306 c are negatively biased with respect to linear thermionic filaments 302 a, 302 b, and 302 c. Insulators 308 a, 308 b, 308 c, 308 d, 308 e, and 308 f electrically insulate and support electrodes 304 a, 304 b, 304 c, 306 a, 306 b, and 306 c. For example, this self-neutralizing ionizer is effective and achieves over 1000 micro Amps argon GCIBs.

Alternatively, ionizers may use electron extraction from plasma to ionize clusters. The geometry of these ionizers is quite different from the three filament ionizer described here but the principles of operation and the ionizer control are very similar. For example, the ionizer design may be similar to the ionizer described in U.S. Pat. No. 7,173,252, entitled IONIZER AND METHOD FOR GAS-CLUSTER ION-BEAM FORMATION; the content of which is incorporated herein by reference in its entirety.

The gas cluster ionizer (122, FIGS. 1, 2 and 3) may be configured to modify the beam energy distribution of GCIB 128 by altering the charge state of the GCIB 128. For example, the charge state may be modified by adjusting an electron flux, an electron energy, or an electron energy distribution for electrons utilized in electron collision-induced ionization of gas clusters.

With reference now to FIGS. 5-9, therein are depicted various embodiments of the multiple nozzle and gas supply assembly of GCIB processing system 100 (or 100′, 100″) of FIGS. 1, 2, and 3, respectively. FIG. 5 depicts an embodiment of a multiple nozzle and gas supply assembly comprising a single gas supply 2010 and two nozzles 2110 and 2120, fed by gas supply 2010. Like, for example, the first gas supply 115 of GCIB processing system 100 of FIG. 1, gas supply 2010 (and all other gas supplies of FIGS. 5-9) may comprise a first gas source, a second gas source, a first gas control valve, a second gas control valve, and a gas metering valve to allow the formation of a gas mixture composed of gases provided by the first and second gas sources, or alternatively to flow only one gas from the first or second gas source. The multiple nozzle and gas supply assembly of FIG. 5 is suitable for GCIB applications where a large gas flow is required of a single gas or gas mixture, necessitating the use of multiple nozzles, so identical or similar stagnation conditions (i.e. pressure and temperature) can be maintained inside stagnation chambers preceding the nozzles, and identical or similarly-sized nozzles can be utilized as those in a prior art single gas supply and single nozzle GCIB system.

FIG. 6 depicts essentially the embodiment of the multiple nozzle and gas supply assembly of GCIB processing system 100 (or 100′, 100″) of FIGS. 1, 2, and 3, respectively. The assembly of FIG. 6 comprises two gas supplies 3010 and 3020, and two gas nozzles 3110 and 3120, allowing its use in GCIB applications requiring the formation of gas cluster beams composed of mixtures of incompatible gases and/or pyrophoric gases. Such incompatible gas mixtures cannot be readily premixed in a single gas supply (e.g. gas supply 2010 of FIG. 5) for injection via a single or multiple nozzles, due to at least adverse chemical reactions that would occur between the incompatible gas mixture components inside the parts and piping of the single gas supply. The multiple nozzle and gas supply assembly of FIG. 6 overcomes this issue by providing independent gas supplies 3010, 3020 for the incompatible and/or pyrophoric gas mixture components, which are only mixed upon injection from nozzles 3110 and 3120 mounted in mutual close proximity so as to at least partially coalesce and produce a single gas cluster beam. A further advantage is that different dilution gases may be used in the different gas mixtures, for example, a first gas mixture may use He as a dilution gas, while a second gas mixture may use Ar. It is also possible to configure gas supplies 3010 and 3020 of the multiple nozzle and gas supply system of FIG. 6 to flow gas mixtures of the same composition to nozzles 3110 and 3120. Furthermore, the multiple nozzle and gas supply assembly of FIG. 6 allows the injection of gas mixtures at different stagnation pressures and/or temperatures, from nozzles 3110 and 3120, for example, if optimum cluster nucleation conditions of gas mixtures are different, and therefore require different stagnation conditions. Stagnation pressure control is achieved generally by setting the gas metering valve of a gas supply, while stagnation temperature control may be achieved by the use of suitable heaters or cooling devices (not shown).

FIG. 7 depicts a multiple nozzle and gas supply assembly similar to that of FIGS. 5 and 6 combined, comprising gas supplies 4010 and 4020, and three nozzles 4110, 4120, and 4130, wherein gas supply 4010 supplies two nozzles, 4110 and 4120 respectively, allowing higher flow rates of one gas mixture, while gas supply 4020 supplies only nozzle 4130. This configuration is suitable for applications requiring high flow rates of one gas mixture component, while retaining the ability to handle incompatible and/or pyrophoric gases. FIG. 8 depicts a similar embodiment to that of FIG. 6, extended to comprise three gas supplies 5010, 5020, and 5030, and three nozzles 5110, 5120, and 5130, allowing independent introduction of three different gas mixtures to the nozzles, if a GCIB process so requires. FIG. 9 depicts a similar assembly to that of FIGS. 5 and 8 combined, comprising three gas supplies 6010, 6020, and 6030, and four nozzles 6110, 6120, 6130, and 6140, wherein gas supply 6010 is connected to nozzles 6110 and 6120, allowing high gas mixture flow rates therethrough, with the ability to independently provide an additional two gas mixture components.

While embodiments of FIGS. 5-9 can, as process conditions may demand, be set to simultaneously flow multiple gases or gas mixtures to the individual nozzles, it is also possible to operate the multiple gas supplies and nozzles in a sequential manner, wherein in a sequence of process steps, at least one step is used that involves simultaneously flowing multiple gases or gas mixtures. For example, in the embodiment of FIG. 6, a first GCIB process step may involve flowing only a single gas or gas mixture, generated by gas supply 3010, and introduced via nozzle 3110, and a second process step may involve first and second gases or gas mixtures, generated by gas supplies 3010 and 3020, and introduced via nozzles 3110 and 3120, respectively.

It is immediately apparent that other embodiments of the multiple nozzle and gas supply assembly are possible, comprising different numbers of nozzles (e.g. higher than four), and different numbers of gas supplies (e.g. higher than three) some of which may be connected to multiple nozzles to accommodate high flow rates, all of which embodiments fall within the scope of the invention.

FIGS. 10A-12B are cross-sectional schematics depicting various spatial arrangements of multiple nozzles, and various cross-sectional shapes of a single gas skimmer to be used with a particular nozzle arrangement. The mutual close proximity of nozzles within the assembly ensure that the individual gas cluster beams leaving the nozzles substantially or at least partially coalesce into a single gas cluster beam before reaching the gas skimmer. The coalescence of gas cluster beams into a single gas cluster beam before reaching the gas skimmer allows the use of same GCIB system components downstream of the gas skimmer as in a prior art single gas supply and single nozzle GCIB system. Given that these downstream components may be the same, it is envisioned that an existing GCIB system can be converted into a multi-nozzle system, with multiple gas supplies, with relatively little modification and/or parts replacement, primarily in the source chamber area of a GCIB system.

FIG. 10A depicts a multiple nozzle assembly comprising two nozzles 7010 and 7020, seen in cross section, mounted side by side (or alternatively oriented vertically one above the other) forming a gas cluster beam which passes through a gas skimmer 7000 of substantially circular cross section. FIG. 10B depicts a similar dual nozzle assembly with an oval or elliptical gas skimmer 7100, aligned with nozzles 7110 and 7120. FIG. 10C depicts a dual nozzle assembly with a twin lobed gas skimmer 7200, aligned with nozzles 7210 and 7220. The embodiments of FIGS. 10A-C can readily be extended to assemblies with larger numbers of nozzles. For example, FIG. 11A depicts an assembly with three nozzles 7310, 7320, and 7330 injecting a gas cluster beam through a substantially circular gas skimmer 7300. FIG. 11B depicts a similar three-nozzle assembly, but with a three-lobed gas skimmer 7400, aligned with the nozzles 7410, 7420, and 7430. In similar vein, FIGS. 12A-B extend the concept to an assembly with four nozzles 7510, 7520, 7530 and 7540, and four nozzles 7610, 7620, 7630 and 7640, respectively, injecting a gas cluster beam through a substantially circular gas skimmer 7500 and four-lobed gas skimmer, 7600, respectively. Other embodiments can be readily envisioned, all of which fall within the scope of the invention.

Furthermore, as depicted in partial schematic view in FIGS. 13A-13D, to assist in gas cluster beam coalescence, the nozzles (three nozzles 410, 412, 414 are shown, but the invention is not so limited) can be mounted at a slight angle pointing towards a single intersecting point 420 along the beam axis 119 of gas cluster beam 118 of FIGS. 1, 2 and 3. For example, the gas cluster beam axes 411, 413, 415 of the individual nozzles 410, 412, 414 can intersect at a single intersecting point 420 along beam axis 119 inside the ionizer 122 (e.g., of GCIB processing system 100 of FIG. 1), as depicted in FIG. 13A. Alternatively, the gas cluster beam axes 411, 413, 415 of the individual nozzles 410, 412, 414 can intersect at a single intersecting point 420 along beam axis 119 downstream of the gas skimmer 120 but upstream of the ionizer 122, as depicted in FIG. 13B. In another alternative, the gas cluster beam axes 411, 413, 415 of the individual nozzles 410, 412, 414 can intersect at a single intersecting point 420 along beam axis 119 between an input and an output of the gas skimmer 120, as depicted in FIG. 13C. Alternatively yet, the gas cluster beam axes 411, 413, 415 of the individual nozzles 410, 412, 414 can intersect at a single intersecting point 420 along beam axis 119 between the output of the nozzles 410, 412, 414 and the input of the gas skimmer 120, as depicted in FIG. 13D. The inward slant angle, i.e. deviation from parallel orientation, can range from 0.5 to 10 degrees, or from 0.5 to 5 degrees, or from 1 to 2 degrees.

Referring now to FIG. 14, a method of irradiating a substrate using a GCIB is illustrated according to an embodiment. The method comprises a flow chart 8000 beginning in 8010 with providing a GCIB processing system with a set of at least two nozzles either arranged in mutual close proximity to ensure coalescence of individual gas cluster beams before reaching a single gas skimmer or arranged so as to have intersecting beam axes, and a first gas supply configured to supply at least a subset of the full set of nozzles (e.g. a single nozzle, or multiple nozzles of the subset) with a gas mixture. The GCIB processing system can be any of the GCIB processing systems (100, 100′ or 100″) described above in FIG. 1, 2 or 3, or any combination thereof, with any arrangement of nozzles and gas supplies shown in FIGS. 5-13D.

In step 8020, a substrate is loaded into the GCIB processing system. The substrate can include a conductive material, a non-conductive material, or a semi-conductive material, or a combination of two or more thereof. Additionally, the substrate may include one or more material structures formed thereon, or the substrate may be a blanket substrate free of material structures. The substrate can be positioned in the GCIB processing system on a substrate holder and may be securely held by the substrate holder. The temperature of the substrate may or may not be controlled. For example, the substrate may be heated or cooled during a film forming process. The environment surrounding the substrate is maintained at a reduced pressure.

In step 8030, a flow of a first gas mixture is started from the first gas supply. The flow of gas through the nozzle, all nozzles, or subset of nozzles connected to the first gas supply forms a gas cluster beam or a coalesced and/or intersected gas cluster beam, which single beam passes through the single gas skimmer into the ionization chamber of the GCIB processing system.

In step 8040, an optional second gas mixture is introduced from an optional second gas supply into all or a subset of the remaining nozzles (i.e. nozzles not supplied by the first gas supply of step 8010, with the first gas mixture of step 8030). The optional second gas mixture may be the same or different than the first gas mixture, and the gas mixtures, if different, may be incompatible. Additionally, one of the gas mixtures may be pyrophoric. The optional second gas mixture also forms a gas cluster beam or beams that coalesces and/or intersects with the beam or beams from the first nozzle or subset of nozzles to form a single gas cluster beam.

In step 8050, the single gas cluster beam is ionized in an ionizer, such as, for example, ionizer 300 of FIG. 4, to form a gas cluster ion beam (GCIB). In step 8060, the GCIB is accelerated by applying a beam acceleration potential to the GCIB.

In step 8070, the GCIB composed of the first gas mixture, and the optional second gas mixture, is used to irradiate the substrate loaded in the GCIB processing system.

The beam acceleration potential and the beam dose can be selected to achieve the desired properties of a layer affected by irradiation with the GCIB, on the substrate. For example, the beam acceleration potential and the beam dose can be selected to control the desired thickness of a deposited or grown layer, or to achieve a desired surface roughness or other modification of an upper layer atop the substrate, or to control the concentration and depth of penetration of a dopant into the substrate. Herein, beam dose is given the units of number of clusters per unit area. However, beam dose may also include beam current and/or time (e.g., GCIB dwell time). For example, the beam current may be measured and maintained constant, while time is varied to change the beam dose. Alternatively, for example, the rate at which clusters irradiate the surface of the substrate per unit area (i.e., number of clusters per unit area per unit time) may be held constant while the time is varied to change the beam dose.

Additionally, other GCIB properties may be varied, including, but not limited to, gas flow rates, stagnation pressures, cluster size, or gas nozzle designs (such as nozzle throat diameter, nozzle length, and/or nozzle divergent section half-angle).

The selection of combinations of gases used for the first and optional second gas mixture depends on the process that the substrate is being subjected to. The deposition or growth of a material layer may include depositing or growing a SiO_(x), SiN_(x), SiC_(x), SiC_(x)O_(y), SiC_(x)N_(y), BN_(x), BSi_(x)N_(y), Ge, SiGe(B), or SiC(P) layer on a substrate or atop an existing layer on a substrate. According to embodiments of the invention, the first or the optional second gas mixture may thus comprise a nitrogen-containing gas, a carbon-containing gas, a boron-containing gas, a silicon-containing gas, a phosphorous-containing gas, a sulfur-containing gas, a hydrogen-containing gas, a silicon-containing gas, or a germanium-containing gas, or a combination of two or more thereof. Examples of gases which may be used to form the first and optional second gas mixture are: He, Ne, Ar, Kr, Xe, Rn, SiH₄, Si₂H₆, C₄H₁₂Si, C₃H₁₀Si, H₃C—SiH₃, H₃C—SiH₂—CH₃, (CH₃)₃—SiH, (CH₃)₄—Si, SiH₂Cl₂, SiCl₃H, SiCl₄, SiF₄, O₂, CO, CO₂, N₂, NO, NO₂, N₂O, NH₃, NF₃, B₂H₆, alkyl silane, an alkane silane, an alkene silane, an alkyne silane, and C_(x)H_(y), where x≧1, and y≧4, and combinations of two or more thereof. The first and optional second gas mixtures are formed by the first and optional second gas supplies of the GCIB processing system.

When depositing silicon, a substrate may be irradiated by a GCIB formed from a first or optional second gas mixture having a silicon-containing gas. For example, a gas mixture may comprise silane (SiH₄). In another example, the gas mixture may comprise disilane (Si₂H₆), dichlorosilane (SiH₂Cl₂), trichlorosilane (SiCl₃H), diethylsilane (C₄H₁₂Si), trimethylsilane (C₃H₁₀Si), silicon tetrachloride (SiCl₄), silicon tetrafluoride (SiF₄), or a combination of two or more thereof.

When depositing or growing an oxide such as SiO_(x), a substrate may be irradiated by a GCIB formed from a first and optional second gas mixture having a silicon-containing gas and an oxygen-containing gas, respectively. For example, the first gas mixture may comprise silane (SiH₄), and the second gas mixture may comprise O₂. In another example, the second gas mixture may comprise O₂, CO, CO₂, NO, NO₂, or N₂O, or any combination of two or more thereof.

When depositing or growing a nitride such as SiN_(x), a substrate may be irradiated by a GCIB formed from a first and optional second gas mixture having a silicon-containing gas and a nitrogen-containing gas, respectively. For example, the first gas mixture may comprise silane (SiH₄), and the second gas mixture may comprise N₂. In another example, the second gas mixture may comprise N₂, NO, NO₂, N₂O, or NH₃, or any combination of two or more thereof.

When depositing a carbide such as SiC_(x), a substrate may be irradiated by a GCIB formed from a pressurized gas mixture having a silicon-containing gas and a carbon-containing gas. For example, the first gas mixture may comprise silane (SiH₄) and CH₄. Alternatively, the first gas mixture may comprise silane (SiH₄) only, and the optional second gas mixture may comprise CH₄. Additionally, for example, the first gas mixture may comprise silane (SiH₄), and the optional second gas mixture may comprise methylsilane (H₃C—SiH₃). Furthermore, for example, the first gas mixture may comprise a silicon-containing gas and CH₄ (or more generally a hydrocarbon gas, i.e., C_(x)H_(y)), and the optional second gas mixture may comprise CO, or CO₂. Further yet, any of the first gas mixture and optional second gas mixture may comprise, for example, alkyl silane, an alkane silane, an alkene silane, or an alkyne silane, or any combination of two or more thereof. Additionally, for example, the first gas mixture may comprise silane, methylsilane (H₃C—SiH₃), dimethylsilane (H₃C—SiH₂—CH₃), trimethylsilane ((CH₃)₃—SiH), or tetramethylsilane ((CH₃)₄—Si), or any combination of two or more thereof. When growing or depositing a carbonitride such as SiC_(x)N_(y), the optional second gas mixture may further comprise a nitrogen-containing gas. For example, the nitrogen-containing gas may include N₂, NH₃, NF₃, NO, N₂O, or NO₂, or a combination of two or more thereof. The addition of a nitrogen-containing gas may permit forming a silicon carbonitride film (SiCN).

When growing or depositing a nitride such as BN_(x), a substrate may be irradiated by a GCIB formed from a first gas mixture having a boron-containing gas and an optional second gas mixture having a nitrogen-containing gas. For example, the first gas mixture may comprise diborane (B₂H₆), and the optional second gas mixture may comprise N₂. In another example, the optional second gas mixture may comprise N₂, NO, NO₂, N₂O, or NH₃, or any combination of two or more thereof.

When growing or depositing a nitride such as BSi_(x)N_(y), a substrate may be irradiated by a GCIB formed from a first gas mixture having a silicon-containing gas, and a optional second gas mixture having a boron-containing gas and a nitrogen-containing gas. For example, the first gas mixture may comprise silane (SiH₄), and the optional second gas mixture may comprise diborane (B₂H₆) and N₂. In another example, the optional second gas mixture may comprise B₂H₆, N₂, NO, NO₂, N₂O, or NH₃, or any combination of two or more thereof.

In other processes, such as for example, infusion, doping, and layer surface modification, in addition to layer growth and deposition, further additional gases may be used to form gas mixtures in gas supplies of a GCIB processing system. These gases include germanium-, phosphorus-, and arsenic-containing gases, such as GeH₄, Ge₂H₆, GeH₂Cl₂, GeCl₃H, methylgermane, dimethylgermane, trimethylgermane, tetramethylgermane, ethylgermane, diethylgermane, triethylgermane, tetraethylgermane, GeCl₄, GeF₄, BF₃, AsH₃, AsF₅, PH₃, PF₃, PCl₃, or PF₅, or any combination of two or more thereof.

In any one of the above examples, the first and/or second gas mixture may comprise an optional inert dilution gas. The dilution gas may comprise a noble gas, such as for example, He, Ne, Ar, Kr, Xe, or Rn, which may be different for the first and second gas mixtures.

Further extending the above process, optional third, fourth, etc., gas mixtures may be introduced (not shown), as the process may require, and if the number of available gas supplies and nozzles installed in the GCIB system, permits.

The inventors have tested the multiple nozzle GCIB system in a SiO₂ deposition process, which may be utilized for blanket SiO₂ deposition, or trench filling, such as shallow trench isolation (STI) structure filling. A similar process may be employed also for growth of a SiO₂ film. The hardware comprised a dual nozzle GCIB system configured with a pressure cell chamber, as in FIG. 3, with two gas supplies. The gas supply configuration of the GCIB system was that of FIG. 6. Each gas supply was configured with two gas sources: a first gas source for the process gas, and a second gas source for a dilution gas. The nozzle configuration used was that depicted in FIG. 10A, with nozzles mounted one above the other, and with a gas skimmer of circular cross section. All other components of the GCIB system were that of a single nozzle, single gas supply GCIB system.

To deposit SiO₂ on a substrate, the first gas supply was configured to flow SiH₄ as a Si-containing gas, which was diluted with He to form a first gas mixture fed into the first nozzle. The total flow rate through the first nozzle was set within the range of 300 to 700 sccm, typically 600 sccm, but the flow rate in a production process may be higher or lower than the above range, e.g. 200 to 1000 sccm. The percentage of SiH₄ in He, in the first gas mixture, was typically set at 10%, but in a production process it may be set higher or lower than 10%, e.g. at 2 to 20%. The second gas supply was configured to flow O₂ as an O-containing gas, through the second nozzle, at a flow rate ranging from 200 to 500 sccm, and optionally diluted with an additional flow of He ranging from 800 to 1100 sccm, to form a second gas mixture. In an actual production process, the flow rates of O₂ and the optional dilution gas may be different. The above flow rate ranges for the two gas mixtures translate into an O₂/SiH₄ ratio ranging from 3.3 to 16.7, which in part determines the SiO₂ film stoichiometry.

Deposition processes were run with the above two gas mixtures, with acceleration potentials V_(Acc) ranging from 10 to 50 kV. The gas flow rate into the pressure cell chamber was either zero (i.e. off), or set at 20 sccm (“20P”), which translates into a pressure-distance integral of about 0.003 Torr-cm. The GCIB beam current under these conditions ranged from 15 to 49 μA.

Deposited SiO₂ films ranged in color from brown to very slightly tinted or colorless, with increasing O₂/SiH₄ ratio. All films showed evidence of compressive stress in acquired FTIR spectra, which is a common feature of most as-deposited GCIB films. The compressive stress can be reduced or eliminated using a post-deposition anneal process, at a temperature ranging from 600 to 1000 degrees C., and of 15 to 60 min duration, for example. The anneal process also causes the film roughness R_(a) to decrease from as-deposited values of 6.9 Å to 7.4 Å, which depend weakly on the GCIB process condition, by about 0.3 Å R_(a). Gap fill experiments were also conducted, in which trenches were successfully filled with SiO₂ before trench pinch-off.

The flowchart in FIG. 15 shows the steps of a process 9000 of formation of a shallow trench isolation (STI) structure using a GCIB system with multiple nozzle and gas supplies. The process of forming an STI using a conventional single nozzle GCIB processing system is discussed in U.S. Provisional Patent Application No. 61/149,917, entitled “METHOD FOR FORMING TRENCH ISOLATION USING GAS CLUSTER ION BEAM PROCESSING” (Ref. No. EP-169 PROV), the entire content of which is herein incorporated by reference in its entirety.

The method begins with step 9010, with providing a GCIB processing system with a set of at least two nozzles either arranged in mutual close proximity to ensure coalescence of individual gas cluster beams before reaching a single gas skimmer or arranged so as to have intersecting beam axes, a first gas supply configured to supply a subset of the full set of nozzles (e.g. a single nozzle, or multiple nozzles of the subset) with a gas mixture, and a second gas supply to supply the remaining nozzles (i.e. nozzles not supplied by the first gas supply). The GCIB processing system can be any of the GCIB processing systems (100, 100′ or 100″) described above in FIG. 1, 2 or 3, with any arrangement of nozzles and gas supplies shown in FIGS. 5-13D.

In step 9020, a substrate is loaded into the GCIB processing system. The substrate can include a conductive material, a non-conductive material, or a semi-conductive material, or a combination of two or more materials thereof. Additionally, the substrate may include one or more material structures formed thereon, or the substrate may be a blanket substrate free of material structures. The substrate can be positioned in the GCIB processing system on a substrate holder and may be securely held by the substrate holder. The temperature of the substrate may or may not be controlled. For example, the substrate may be heated or cooled during a film forming process. The environment surrounding the substrate is maintained at a reduced pressure.

In step 9030, a flow of a first gas mixture is started from the first gas supply. The flow of gas through the nozzle or subset of nozzles connected to the first gas supply forms a gas cluster beam which passes through the single gas skimmer into the ionization chamber of the GCIB processing system.

In step 9040, a second gas mixture is introduced from the second gas supply into all or a subset of the remaining nozzles (i.e. nozzles not supplied by the first gas supply) to form a gas cluster beam or beams that coalesces and/or intersects with the beam or beams from the first nozzle or subset of nozzles to form a single gas cluster beam.

In step 9050, the single gas cluster beam is ionized in an ionizer, such as, for example, ionizer 300 of FIG. 4, to form a gas cluster ion beam (GCIB). In step 9060, the GCIB is accelerated by applying a beam acceleration potential to the GCIB.

In step 9070, the GCIB composed of the first gas mixture and the second gas mixture is used to irradiate the substrate loaded in the GCIB processing system, to form an STI structure on the substrate, or on a layer atop the substrate. The STI structure can be used, for example, in a memory device.

To form an SiO2 STI structure, i.e. to fill the STI trench with SiO2, the first gas mixture may comprise a silicon-containing gas. For example, the first gas mixture may comprise SiH4, Si2H6, C4H12Si, C3H10Si, H3C—SiH3, H3C—SiH2—CH3, (CH3) 3—SiH, (CH3)4—Si, SiH2Cl2, SiCl3H, SiCl4, SiF4, alkyl silane, an alkane silane, an alkene silane, an alkyne silane, or any combination of two or more thereof. Optionally, the first gas mixture may further comprise an inert dilution gas. The dilution gas may comprise a noble gas, such as for example, He, Ne, Ar, Kr, Xe, or Rn. To form the STI structure, the second gas mixture may comprise an oxygen-containing gas. For example, the second gas mixture may comprise O2, CO, CO2, NO, NO2, N2O, or any combination of two or more thereof. Optionally, the second gas mixture may further comprise an inert dilution gas. The dilution gas may comprise a noble gas, such as for example, He, Ne, Ar, Kr, Xe, or Rn, or any combination of two or more thereof.

Referring now to FIGS. 16A through 16F, a method of irradiating a substrate with a GCIB is provided according to several embodiments. As described above, a GCIB processing system is provided that comprises a set of at least two nozzles for forming and emitting gas cluster beams, and a substrate to be processed, i.e., to be irradiated with one or more GCIBs, is loaded into the GCIB processing system. At least one region on the substrate is irradiated with a first GCIB formed using the set of at least two nozzles, and at least one region on the substrate is irradiated with a second GCIB formed using the set of at least two nozzles. Also, as described above, the first GCIB and the second GCIB are directed along a beam axis common to both the first and second GCIB. For example, the set of at least two nozzles are either arranged in mutual close proximity to ensure coalescence of individual gas cluster beams before reaching a single gas skimmer or arranged so as to have intersecting gas cluster beam axes.

In one embodiment, as shown in FIG. 16A, a time sequence 9100 is provided, wherein irradiation of at least a portion of the substrate with a first GCIB 9110 and irradiation of at least a portion of the substrate with a second GCIB 9120 are performed simultaneously at least in part or fully during the period of time irradiation occurs. The first GCIB 9110 and the second GCIB 9120 are formed using at least one nozzle in the set of at least two nozzles. For example, the first GCIB 9110 may be formed using a first nozzle in the set of at least two nozzles and the second GCIB 9120 may be formed using a second nozzle in the set of at least two nozzles.

In another embodiment, as shown in FIG. 16B, a time sequence 9200 is provided, wherein irradiation of at least a portion of the substrate with a first GCIB 9210 and irradiation of at least a portion of the substrate with a second GCIB 9220 are performed sequentially. The sequential irradiation of the substrate with the first GCIB 9210 and the second GCIB 9220 may alternate cyclically (as shown) or acyclically. The alternation of the first GCIB 9210 and the second GCIB 9220 may proceed for one or more cycles. The sequential and alternating irradiation of the substrate with the first GCIB 9210 may include setting a pulse width 9212 during which the first GCIB 9210 irradiates the substrate and a cycle (or on/off) period 9214. Further, the sequential and alternating irradiation of the substrate with the second GCIB 9220 may include setting a pulse width 9222 during which the second GCIB 9220 irradiates the substrate and a cycle (or on/off) period 9224. The first GCIB 9210 and the second GCIB 9220 are formed using at least one nozzle in the set of at least two nozzles. For example, the first GCIB 9210 may be formed using a first nozzle in the set of at least two nozzles and the second GCIB 9220 may be formed using a second nozzle in the set of at least two nozzles.

In another embodiment, as shown in FIG. 16C, a time sequence 9300 is provided, wherein irradiation of at least a portion of the substrate with a first GCIB 9310 and irradiation of at least a portion of the substrate with a second GCIB 9320 are performed sequentially. The sequential irradiation of the substrate with the first GCIB 9310 and the second GCIB 9320 may alternate cyclically (as shown) or acyclically. The alternation of the first GCIB 9310 and the second GCIB 9320 may proceed for one or more cycles. The sequential and alternating irradiation of the substrate with the first GCIB 9310 may include setting a pulse width 9312 during which the first GCIB 9310 irradiates the substrate and a cycle (or on/off) period 9314. Further, the sequential and alternating irradiation of the substrate with the second GCIB 9320 may include setting a pulse width 9322 during which the second GCIB 9320 irradiates the substrate and a cycle (or on/off) period 9324. Moreover, the sequential irradiation of the substrate with the first and second GCIBs (9310, 9320) may proceed with one or more time periods, e.g., an initial time delay 9330 and a final time delay 9340, inserted between the respective substrate irradiations. The first GCIB 9310 and the second GCIB 9320 are formed using at least one nozzle in the set of at least two nozzles. For example, the first GCIB 9310 may be formed using a first nozzle in the set of at least two nozzles and the second GCIB 9320 may be formed using a second nozzle in the set of at least two nozzles.

In another embodiment, as shown in FIG. 16D, a time sequence 9400 is provided, wherein irradiation of at least a portion of the substrate with a first GCIB 9410 and irradiation of at least a portion of the substrate with a second GCIB 9420 are performed sequentially. The sequential irradiation of the substrate with the first GCIB 9410 and the second GCIB 9420 may alternate cyclically (as shown) or acyclically. The alternation of the first GCIB 9410 and the second GCIB 9420 may proceed for one or more cycles. Further, the sequential irradiation of the substrate with the first and second GCIBs (9410, 9420) may proceed with one or more time periods inserted between the respective substrate irradiations during which at least one nozzle in the set of at least two nozzles is purged with a purge gas 9430. The first GCIB 9410 and the second GCIB 9420 are formed using at least one nozzle in the set of at least two nozzles. For example, the first GCIB 9410 may be formed using a first nozzle in the set of at least two nozzles and the second GCIB 9420 may be formed using a second nozzle in the set of at least two nozzles.

In another embodiment, as shown in FIG. 16E, a time sequence 9500 is provided, wherein irradiation of at least a portion of the substrate with a first GCIB 9510 and irradiation of at least a portion of the substrate with a second GCIB 9520 are performed sequentially. The sequential irradiation of the substrate with the first GCIB 9510 and the second GCIB 9520 may alternate cyclically (as shown) or acyclically. The alternation of the first GCIB 9510 and the second GCIB 9520 may proceed for one or more cycles. The sequential and alternating irradiation of the substrate with the first GCIB 9510 may include setting a pulse width 9512 during which the first GCIB 9510 irradiates the substrate and a cycle (or on/off) period 9514. Further, the sequential and alternating irradiation of the substrate with the second GCIB 9520 may include setting a pulse width 9522 during which the second GCIB 9520 irradiates the substrate and a cycle (or on/off) period 9524. Moreover, the sequential irradiation of the substrate with the first and second GCIBs (9510, 9520) may proceed with one or more time periods, e.g., an initial time overlap 9530 and a final time overlap 9540, during which the respective substrate irradiations partially overlap. The first GCIB 9510 and the second GCIB 9520 are formed using at least one nozzle in the set of at least two nozzles. For example, the first GCIB 9510 may be formed using a first nozzle in the set of at least two nozzles and the second GCIB 9520 may be formed using a second nozzle in the set of at least two nozzles.

In another embodiment, as shown in FIG. 16F, a time sequence 9600 is provided, wherein irradiation of at least a portion of the substrate with a first GCIB 9610 is performed simultaneously or continuously while at least a portion of the substrate is sequentially irradiated with a second GCIB 9620 and a third GCIB 9630. The sequential irradiation of the substrate with the second GCIB 9620 and the third GCIB 9630 may alternate cyclically (as shown) or acyclically. The alternation of the second GCIB 9620 and the third GCIB 9630 may proceed for one or more cycles. The first GCIB 9610 may be formed using a first nozzle in the set of at least two nozzles, and the second GCIB 9620 and the third GCIB 9630 may be formed using a second nozzle in the set of at least two nozzles. Alternatively, the first GCIB 9610 may be formed using a first nozzle in the set of at least two nozzles, the second GCIB 9620 may be formed using a second nozzle in the set of at least two nozzles, and the third GCIB 9630 may be formed using a third nozzle in the set of at least two nozzles.

It is immediately apparent that other embodiments for simultaneous and/or sequential operation of the multiple nozzle and gas supply assembly are possible, comprising different numbers of nozzles, and different numbers of gas supplies, all of which embodiments fall within the scope of the invention. Any one or more of the embodiments described in FIGS. 16A through 16F may be combined.

Turning now to FIG. 17, a method of irradiating a substrate with a GCIB is provided. The method comprises a flow chart 10000 beginning in 10100 with providing a GCIB processing system having a set of at least two nozzles for forming and emitting gas cluster beams. The GCIB processing system may include any one of the systems described above.

In 10200, a substrate to be processed is loaded into the GCIB processing system.

In 10300, at least one region on the substrate is sequentially first irradiated with a first GCIB formed using a first subset of nozzles in the set of at least two nozzles.

In 10400, at least one region on the substrate is sequentially second irradiated with a second GCIB formed using a second subset of nozzles in the set of at least two nozzles that is different than the first subset of nozzles.

The first GCIB and the second GCIB may have the same atomic and/or molecular constituents. Alternatively, the first GCIB and the second GCIB have different atomic and/or molecular constituents. The first GCIB and the second GCIB comprise one or more elements selected from the group consisting of H, B, C, Si, Ge, N, P, As, O, S, F, Cl, Br, He, Ne, Ar, Kr, or Xe.

One or more gas supply parameters selected from the group consisting of stagnation pressure and stagnation temperature may be the same for the first GCIB and the second GCIB. Alternatively, one or more gas supply parameters selected from the group consisting of stagnation pressure and stagnation temperature may be different for the first GCIB and the second GCIB. Additionally, one or more process parameters selected from the group consisting of beam energy, beam energy distribution, beam focus, and beam dose may be the same for the first GCIB and the second GCIB. Alternatively, one or more process parameters selected from the group consisting of beam energy, beam energy distribution, beam focus, and beam dose are different for the first GCIB and the second GCIB.

The irradiating at least one region on the substrate with the first GCIB performs one or more processes on the substrate selected from the group consisting of doping, growing, depositing, etching, smoothing, amorphizing, or modifying a layer thereupon. And, the irradiating at least one region on the substrate with the second GCIB performs one or more processes on the substrate selected from the group consisting of doping, growing, depositing, etching, smoothing, amorphizing, or modifying a layer thereupon.

In one example, a substrate may be irradiated with a first GCIB to amorphize a surface layer of the substrate. Thereafter, the substrate may be irradiated with a second GCIB to dope or infuse material into the amorphized surface layer.

In another example, a substrate may be irradiated with a first GCIB to grow or deposit a material layer on the substrate. Thereafter, the substrate may be irradiated with a second GCIB to smooth or modify a surface of the deposited material layer.

In another example, a substrate may be irradiated with a first GCIB to dope a surface layer on the substrate. Thereafter, the substrate may be irradiated with a second GCIB to smooth or modify a surface of the doped material layer.

In another example, a substrate may be irradiated with a first GCIB to deposit a material layer on the substrate. Thereafter, the substrate may be irradiated with a second GCIB to grow a second material layer in the deposited material layer.

In another example, a substrate may be irradiated with a first GCIB to modify a material layer on the substrate by introduction or removal of a first material. Thereafter, the substrate may be irradiated with a second GCIB to further modify the modified material layer on the substrate by introduction or removal of a second material.

In yet another example, a substrate may be irradiated with a first GCIB to clean or etch a surface layer on the substrate. Thereafter, the substrate may be irradiated with a second GCIB to grow or deposit a material layer on the cleaned or etched surface layer.

Reference throughout this specification to “one embodiment” or “an embodiment” means that a particular feature, structure, material, or characteristic described in connection with the embodiment is included in at least one embodiment of the invention, but do not denote that they are present in every embodiment. Thus, the appearances of the phrases “in one embodiment” or “in an embodiment” in various places throughout this specification are not necessarily referring to the same embodiment of the invention. Furthermore, the particular features, structures, materials, or characteristics may be combined in any suitable manner in one or more embodiments.

Various operations may have been described as multiple discrete operations in turn, in a manner that is most helpful in understanding the invention. However, the order of description should not be construed as to imply that these operations are necessarily order dependent. In particular, these operations need not be performed in the order of presentation. Operations described may be performed in a different order than the described embodiment. Various additional operations may be performed and/or described operations may be omitted in additional embodiments.

Persons skilled in the relevant art can appreciate that many modifications and variations are possible in light of the above teaching. Persons skilled in the art will recognize various equivalent combinations and substitutions for various components shown in the figures. It is therefore intended that the scope of the invention be limited not by this detailed description, but rather by the claims appended hereto. 

1. A method of irradiating a substrate with a gas cluster ion beam (GCIB), comprising: providing a GCIB processing system comprising a set of at least two nozzles for forming and emitting gas cluster beams; loading a substrate to be processed into the GCIB processing system; irradiating at least one region on the substrate with a first GCIB formed using the set of at least two nozzles; and irradiating at least one region on the substrate with a second GCIB formed using the set of at least two nozzles, wherein the first GCIB and the second GCIB are directed along a beam axis common to both the first and second GCIB.
 2. The method of claim 1, wherein the GCIB processing system further comprises a gas skimmer, and at least one gas supply in fluid communication with a first subset of nozzles and with a second subset of nozzles different than the first subset of nozzles, the first and second subset of nozzles each comprising at least one nozzle from the set of at least two nozzles, and wherein each nozzle in the set of at least two nozzles is configured for forming and emitting a gas cluster beam, and the set of at least two nozzles are arranged in mutual close proximity and capable of at least partially coalescing each of the gas cluster beams emitted from the set of at least two nozzles into the gas skimmer and along the beam axis.
 3. The method of claim 2, wherein the at least one gas supply comprises: a first gas supply in fluid communication with the first subset of nozzles; and a second gas supply in fluid communication with the second subset of nozzles.
 4. The method of claim 2, wherein: the irradiating at least one region on the substrate with the first GCIB comprises: flowing a first gas mixture from the at least one gas supply through at least the first subset of nozzles to form a first gas cluster beam, directing the first gas cluster beam through the gas skimmer along the beam axis and then ionizing the first gas cluster beam to form the first GCIB, and accelerating the first GCIB toward the substrate; and the irradiating at least one region on the substrate with the second GCIB comprises: flowing a second gas mixture from the at least one gas supply through at least the second subset of nozzles to form a second gas cluster beam, directing the second gas cluster beam through the gas skimmer along the beam axis and then ionizing the second gas cluster beam to form a second GCIB, and accelerating the second GCIB toward the substrate.
 5. The method of claim 1, wherein the first GCIB and the second GCIB have the same atomic and/or molecular constituents.
 6. The method of claim 1, wherein the first GCIB and the second GCIB have different atomic and/or molecular constituents.
 7. The method of claim 1, wherein the first GCIB and the second GCIB comprise one or more elements selected from the group consisting of H, B, C, Si, Ge, N, P, As, O, S, F, Cl, Br, He, Ne, Ar, Kr, or Xe.
 8. The method of claim 1, wherein one or more gas supply parameters selected from the group consisting of stagnation pressure and stagnation temperature are the same for the first GCIB and the second GCIB.
 9. The method of claim 1, wherein one or more gas supply parameters selected from the group consisting of stagnation pressure and stagnation temperature are different for the first GCIB and the second GCIB.
 10. The method of claim 1, wherein one or more process parameters selected from the group consisting of beam energy, beam energy distribution, beam focus, and beam dose are the same for the first GCIB and the second GCIB.
 11. The method of claim 1, wherein one or more process parameters selected from the group consisting of beam energy, beam energy distribution, beam focus, and beam dose are different for the first GCIB and the second GCIB.
 12. The method of claim 1, wherein the irradiating at least one region on the substrate with the first GCIB performs one or more processes on the substrate selected from the group consisting of doping, growing, depositing, etching, smoothing, amorphizing, or modifying a layer thereupon.
 13. The method of claim 1, wherein the irradiating at least one region on the substrate with the second GCIB performs one or more processes on the substrate selected from the group consisting of doping, growing, depositing, etching, smoothing, amorphizing, or modifying a layer thereupon.
 14. The method of claim 1, further comprising: simultaneously performing the irradiating at least a portion of the substrate with the first GCIB and the irradiating at least a portion of the substrate with the second GCIB.
 15. The method of claim 1, further comprising: sequentially performing the irradiating at least a portion of the substrate with the first GCIB and the irradiating at least a portion of the substrate with the second GCIB.
 16. The method of claim 15, wherein the sequentially performing includes a partial overlap between the irradiating at least a portion of the substrate with the first GCIB and the irradiating at least a portion of the substrate with the second GCIB.
 17. The method of claim 1, further comprising: alternatingly and sequentially performing the irradiating at least a portion of the substrate with the first GCIB and the irradiating at least a portion of the substrate with the second GCIB.
 18. The method of claim 1, wherein the GCIB processing system further comprises a gas skimmer, and at least one gas supply in fluid communication with a first subset of nozzles and with a second subset of nozzles different than the first subset of nozzles, the first and second subset of nozzles each comprising at least one nozzle from the set of at least two nozzles, and wherein each nozzle in the set of at least two nozzles is configured for forming and emitting a gas cluster beam having a gas cluster beam axis, and the set of at least two nozzles are angled to converge each gas cluster beam axis toward a single intersecting point and direct one or more gas cluster beams into the gas skimmer along the beam axis.
 19. A method of irradiating a substrate with a gas cluster ion beam (GCIB), comprising: providing a GCIB processing system having a set of at least two nozzles for forming and emitting gas cluster beams; loading a substrate to be processed into the GCIB processing system; sequentially first, irradiating at least one region on the substrate with a first GCIB formed using a first subset of nozzles in the set of at least two nozzles; and sequentially second, irradiating at least one region on the substrate with a second GCIB formed using a second subset of nozzles in the set of at least two nozzles, being different than the first subset of nozzles.
 20. The method of claim 19, wherein the sequentially second irradiating partially overlaps the sequentially first irradiating. 